Method for Administering Solid Water Particles to Prevent Bacteria Growth in Living Organisms

ABSTRACT

A method for administering solid water particles to prevent bacteria growth in living organisms utilizes a solid water particle (SWP) solution to attract and kill a bacterium through polarization. The method inhibits growth of a bacterium or an enveloped virus with an inorganic solution comprised substantially of SWP. The SWP kill the bacterium by providing a solution comprised substantially of SWP having inherent dipole characteristics that generate an electric field. The generated electric field attracts a bacterium to the SWP. Once engaged, the bacterium cannot move. The electric field also creates sufficient internal pressure in the bacterium, which bursts the cell walls of the bacterium, thereby killing bacterium. This mechanism also kills superbug, which are drug resistant bacteria. The method is also efficacious for killing enveloped viruses in the same manner. Further, administering the SWP solution into the mouth for a duration, helps reduce tooth pain and treat periodontal diseases.

CROSS REFERENCE OF RELATED APPLICATIONS

This application claims the benefits of U.S. provisional application No.62/836,940, filed Apr. 22, 2019 and entitled a METHOD FOR INHIBITINGGROWTH OF BACTERIA, SUPERBUG AND VIRUS WITH SOLID WATER PARTICLES, whichprovisional application is incorporated by reference herein in itsentirety.

FIELD OF THE INVENTION

The present invention relates generally to a method for administeringsolid water particles to prevent bacteria growth in living organisms.More so, the present invention relates to a method that leverages thedipole properties of solid water particles (SWP) to capture and killbacterium through oral and topical administration thereof.

BACKGROUND OF THE INVENTION

The following background information may present examples of specificaspects of the prior art (e.g., without limitation, approaches, facts,or common wisdom) that, while expected to be helpful to further educatethe reader as to additional aspects of the prior art, is not to beconstrued as limiting the present invention, or any embodiments thereof,to anything stated or implied therein or inferred thereupon.

Typically, solid water particles consist of numerous molecules, whichare comprised of two hydrogens and one oxygen, clustering together. Thesolid water particle is a new solid state of water that does not melt atroom temperature and pressure, so as to avoid the implication of aliquid state. It is well known that even distilled water will growbacteria after some time. This occurs because seeds of algae maycontaminate the distilled water. With water, some light, and a smallamount of dissolved carbon dioxide, algae can photosynthesize andmultiply. Algae may then become the food for bacteria to grow.

Generally, solid water particles exhibit unique dipole electricalproperties, generating an electric field. The electric field is strongerfor smaller clusters of solid water particle, and weaker for largerclusters of solid water particle, due to the negating effects of greaternumber of solid water particles. However, the smaller clusters of solidwater particles having the larger electric fields are generally disposedat the outer regions of the solid water particle cluster, which enhancesthe polarizing effect thereof.

It is recognized that superbugs are bacteria that develop drug-resistantability. Most current antibiotics disrupt the biochemical reactions ofthe bacteria. Specifically, they inhibit DNA synthesis, RNA synthesis,cell wall synthesis, or protein synthesis of the bacteria. Superbugs donot develop electric-field resistant ability. As solid water particlekills bacteria with extremely high electric field, so it will kill andinhibit the growth of superbugs, which are resistant to currentantibiotics.

Other proposals have involved anti-virus medical treatments and medicalsolutions. The problem with these treatments is that they do not utilizesolid water particles. Also, the administration is not always possiblethrough both oral and topical means. Even though the above citedanti-virus medical treatments meet some of the needs of the market, amethod that leverages the dipole properties of solid water particles(SWP) to capture and kill bacterium through oral and topicaladministration thereof, is still desired.

SUMMARY

Illustrative embodiments of the disclosure are generally directed to amethod for administering solid water particles to prevent bacteriagrowth in living organisms. The method leverages the dipole propertiesof solid water particles (SWP) to capture and kill bacterium throughoral administration thereof. The dipole properties of the SWP generatesan electric field that can be enhanced for drawing the bacterium to theSWP particle; and then creates internal pressure on the cell walls ofthe bacterium—killing the bacterium.

In some embodiments, the method provides discrete steps that include theutilization of a solution of SWP to attract and kill a bacterium throughpolarization. The method inhibits growth of a bacterium or an envelopedvirus with an inorganic solution comprised substantially of SWP. The SWPkill the bacterium by providing a solution comprised substantially ofSWP having inherent dipole characteristics that generate an electricfield. The generated electric field attracts a bacterium to the SWP.

Once the SWP particle and bacterium are electrically engaged,escape/movement by the bacterium is restricted. The electric field alsocreates sufficient internal pressure in the bacterium, which bursts thecell walls of the bacterium, thereby killing bacterium. This mechanismalso kills superbug, which are drug resistant bacteria. The method isalso efficacious for killing enveloped viruses in the same manner.Further, administering the SWP solution into the mouth for a duration,reduces tooth pain, and treats periodontal diseases.

One aspect of the method for inhibiting growth of bacteria with solidwater particles, comprises an initial Step of providing a solution ofsolid water particles, the solid water particles defined by a positivedipole operable to generate an electric field.

Another Step includes administering the solution of solid waterparticles on an affected area having a bacterium.

The method also includes a Step of inducing, through the electric fieldgenerated by the solid water particles, polarization of the bacterium.

A Step comprises, whereby the bacterium is electrically drawn to thesolid water particles.

A further Step comprises, whereby the polarization generates an internalpressure in the bacterium.

A final Step comprises, whereby the cell walls of the bacterium aredestroyed by the internal pressure.

In another aspect, the solution of solid water particles is operable toprevent the growth of a superbug.

In another aspect, the solution of solid water particles is operable toprevent growth of an enveloped virus.

In another aspect, the method is configured to inhibit bacteria growthin livestock, including: chickens, cows, sheep, and horses.

In another aspect, the solid water particle comprises a plurality ofsolid water particles that form a cluster.

In another aspect, the cluster of solid water particles is rod shaped.

In another aspect, the solid water particle is the solvent in thesolution.

In another aspect, the solution of solid water particles is administeredtopically and orally.

In another aspect, the solution of solid water particles is operable toinhibit bacteria and virus growth in the mouth, gums, teeth, ears, nose,skin, eyes, penis, and vulva.

In another aspect, the solution of solid water particles reduces painand inflammation of the teeth and oral cavity, caused by gingilis andperiodontitis.

In another aspect, the solution of solid water particles reduces painand inflammation in the gums and teeth, whereby the solution of solidwater particles is held in the mouth for a duration.

In another aspect, the method also serves to enhance the dipol effect ofthe solid water particles by manipulating a magnet or a magneticmetamaterial between proximal and distal positions from the solution ofsolid water particles to further induce the generated electric field.

In another aspect, the method also serves to produce the solid waterparticles by: immersing a culture the bacterium in water with the solidwater particles in suspension; drying the specimen of the bacterium on acopper grid that is used for a transmission electron microscope; andextracting a small specimen of the bacterium.

In another aspect, the solid water particle is an inorganic solution.

In another aspect, the inorganic solution is administered topically andorally.

In another aspect, the method is configured to inhibit bacteria growthin the mouth and eyes.

In another aspect, the method is configured to inhibit bacteria growthin livestock, such as chickens and cows.

One objective of the present invention is to kill bacteria, includingsuperbugs, through dipolar interaction with solid water particles.

Another objective is to enhance the dipolar effect of the solid waterparticles on the bacterium through an external source, including amagnet.

Another objective is to inhibit growth of bacteria in the mouth andeyes.

Another objective is to provide an inorganic solution comprised chieflyof SWP to inhibit growth of bacteria.

Another objective is to provide an inexpensive anti-bacterial solution.

Another objective is to provide a method for administering solid waterparticles to prevent bacteria growth in living organisms that can beapplied easily through topical or oral means known in the art.

Other systems, devices, methods, features, and advantages will be orbecome apparent to one with skill in the art upon examination of thefollowing drawings and detailed description. It is intended that allsuch additional systems, methods, features, and advantages be includedwithin this description, be within the scope of the present disclosure,and be protected by the accompanying claims and drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be described, by way of example, with referenceto the accompanying drawings, in which:

FIG. 1 illustrates a flowchart diagram of an exemplary method foradministering solid water particles to prevent bacteria growth in livingorganisms, in accordance with an embodiment of the present invention;

FIG. 2 illustrates a top view of a solid water particle cluster and anE. coli bacterium, in accordance with an embodiment of the presentinvention under a transmission electron microscope;

FIG. 3 illustrates an enlarged view of the bacterium shown in FIG. 2,under a transmission electron microscope, in accordance with anembodiment of the present invention;

FIG. 4 illustrates a closeup view of the internal structure of a micronsize rod shaped solid water particle cluster, in accordance with anembodiment of the present invention;

FIG. 5 illustrates a graphic representation of the induced polarizationof the bacterium by the rod-shaped solid water particle cluster shown inFIG. 4, in accordance with an embodiment of the present invention;

FIG. 6 illustrates a graphical representation of the bacterium shown inFIG. 5 bursting after engaging the rod-shaped solid water particlecluster, in accordance with an embodiment of the present invention;

FIGS. 7A and 7B illustrate an X-ray image of teeth from an individualsuffering from gum and tooth decay, where FIG. 7A shows the teeth beforetreatment with an inorganic solution of solid water particles. FIG. 7Bshows the teeth after treatment, in accordance with an embodiment of thepresent invention;

FIG. 8 illustrates a comparison between two thermograph images of twoindividuals, showing the hottest portions of the body are shown inwhite, with the color gradient going from red to blue to black from hotto cold, in accordance with an embodiment of the present invention;

FIG. 9 illustrates exemplary before and after thermograph images of abody suffering from tooth problems, in accordance with an embodiment ofthe present invention; and

FIG. 10 illustrates thermograph images of an individual similar to FIG.9, with red hot spots and white-hot spots indicating bacterialinflammation, in accordance with an embodiment of the present invention.

Like reference numerals refer to like parts throughout the various viewsof the drawings.

DETAILED DESCRIPTION OF THE INVENTION

The following detailed description is merely exemplary in nature and isnot intended to limit the described embodiments or the application anduses of the described embodiments. As used herein, the word “exemplary”or “illustrative” means “serving as an example, instance, orillustration.” Any implementation described herein as “exemplary” or“illustrative” is not necessarily to be construed as preferred oradvantageous over other implementations. All of the implementationsdescribed below are exemplary implementations provided to enable personsskilled in the art to make or use the embodiments of the disclosure andare not intended to limit the scope of the disclosure, which is definedby the claims. For purposes of description herein, the terms “upper,”“lower,” “left,” “rear,” “right,” “front,” “vertical,” “horizontal,” andderivatives thereof shall relate to the invention as oriented in FIG. 1.Furthermore, there is no intention to be bound by any expressed orimplied theory presented in the preceding technical field, background,brief summary or the following detailed description. It is also to beunderstood that the specific devices and processes illustrated in theattached drawings, and described in the following specification, aresimply exemplary embodiments of the inventive concepts defined in theappended claims. Specific dimensions and other physical characteristicsrelating to the embodiments disclosed herein are therefore not to beconsidered as limiting, unless the claims expressly state otherwise.

A method 100 for administering solid water particles to prevent bacteriagrowth in living organisms is referenced in FIGS. 1-10 The method 100provides an efficient, non-invasive medical procedure for killingbacterium, including superbugs and other communicable viruses known inthe art. The unique dipolar characteristics of solid water particles areapplied to the bacterium to draw the bacterium into proximity or fullengagement with the solid water particles; and then the electricaldipolar force naturally works to crush the cell walls of the bacterium.In some embodiments, the method provides steps for formulating asolution of the solid water particles. In other embodiments, the methodprovides steps for enhancing the dipolar effects from the solid waterparticles, so as to increase efficacy of killing the bacterium.

In one exemplary use, the method 100 provides a unique inorganicsolution comprised substantially of solid water particles that formsolid water particle clusters 202. The solid water particle clusters 202have sufficient polarity to induce a strong electric field. The electricfield is effective for polarizing, attracting, and killing a bacterium204. Further, the method 100 is unique in that a solution of the solidwater particles is operable to prevent the growth of a superbug and/oran enveloped virus. Those skilled in the art will recognize thatsuperbugs are bacteria that develop drug-resistant ability. Most currentantibiotics disrupt the biochemical reactions of the bacteria.Specifically, they inhibit DNA synthesis, RNA synthesis, cell wallsynthesis, or protein synthesis of the bacteria. Superbugs do notdevelop electric-field resistant ability. As SWP kills bacteria withextremely high electric field., so it will kill and inhibit the growthof superbugs, which are resistant to current antibiotics. The method 100is also efficacious for preventing bacteria growth in livestock, suchas, chickens, cows, sheep, and horses.

A flowchart diagram for an exemplary method 100 for administering solidwater particles to prevent bacteria growth in living organisms, isreferenced in FIG. 1. The steps described in the method 100 areexemplary, and may include additional steps; or may be operable withless steps than described. The order/sequence of the steps may berandomly applied, as required for treating different types of viruses,bacteria, fungi, and the like.

The method 100 works to prevent growth of bacteria through use of asolution of solid water particles, with the method 100 comprising aninitial Step 102 of providing a solution of solid water particles, thesolid water particles defined by an electric dipole operable to generatean electric field. In some embodiments, the solid water particlecomprises a plurality of solid water particles that form a cluster. Thecluster may be rod-shaped. And the solid water particle is the solventin the solution. In one non-limiting embodiment, the solution of solidwater particles comprises an inorganic solution. The inorganic solutionis administered topically and orally.

The production of the solid water particles is also taught in the method100. This may include the steps of immersing a culture the bacterium inwater with the solid water particles in suspension.

It is known in the art that multiple SWPs form a cluster having agenerally curved rod shape. FIG. 2 illustrates an image 200 of anexemplary SWP cluster 202 and a bacterium 204. The image is shown at ascale of 500 nm. On the lower region of the image 200, a faint image ofa curved rod appears. This represents the SWP cluster 202. The mass ofdark broken pieces adjacent to the SWP cluster 202 represents thebursting of a cell wall 600 of the bacterium 204, and specifically an E.coli bacterium. FIG. 3 illustrates a five-time enlargement of thebacterium 204 shown in FIG. 2. The scale of the bacterium 204 in FIG. 3is about 100 nm, which allows the broken pieces of the E. coli bacteriato be more visible.

The SWP cluster 202, like the individual SWPs, has a positive dipole502. The positive dipole 502 generates a strong electric field thatworks to attract and create internal pressure in objects, such as abacterium 204. In some embodiments, the SWP cluster 202 generates anelectric dipole. The electric dipole 502 emits a strong electric fieldthat is effective in polarizing surrounding objects, and especiallyobjects having a negative dipole 504. Those skilled in the art willrecognize that the electric field is stronger for smaller clusters ofSWP, and weaker for larger clusters of SWP, due to the negating effectsof greater number of SWPs. However, the smaller clusters of SWPs havingthe larger electric fields are generally disposed at the outer regionsof the SWP cluster 202, which enhances the polarizing effect thereof.

In some embodiments, the emitted electric field is efficacious forattracting the bacterium 204 to the SWP cluster 202. Specifically, thewater inside a cell wall 600 of the bacterium 204 is induced intopolarization to attract to the bacterium 500. The bacterium 500 that isattracted is generally proximal to the SWP cluster 202. Once engagedwith the SWP cluster 202, the strong electrical field restricts thebacterium 204 from disengaging therefrom.

Further, the electric field creates an internal pressure in thebacterium 204. The internal pressure increases inside the cell wall 600of the bacterium 204 until reaching a critical point that kills, orbursts, the bacterium 204. This is because the cell wall 600 of thebacterium cannot withstand excessive pressure. Also, the outer surfaceof the SWP cluster is generally rigid relative to the cell wall 600.

The SWP is made up of many molecules, which are comprised of twohydrogens and one oxygen, clustering together. Those skilled in the artwill recognize that SWP is a new solid state of water that does not meltat room temperature and pressure, so as to avoid the implication of aliquid state. It is well known that even distilled water will growbacteria after some time. This occurs because seeds of algae maycontaminate the distilled water. With water, some light, and a smallamount of dissolved carbon dioxide, algae can photosynthesize andmultiply. Algae may then become the food for bacteria to grow.

The micron size rod of SWP cluster 202 shown in FIG. 2 consists of asmaller SWP which is around several hundred nanometers. The hundrednanometers sized SWP in turn consists of 30 to 50 nanometer SWP. FIG. 4illustrates the internal structure of a micron size rod shaped SWPcluster 400. The rod shaped SWP cluster 400 is made up of hundreds ofnanometers in size, which in turn is made up of smaller ones that are inthe tens of nanometers in size.

Another Step 104 includes administering the solution of solid waterparticles on an affected area having a bacterium. The inorganic solutionof SWP may be administered topically or orally. In one experimentalembodiment, drinking and dropping the inorganic solution of SWP into theeyes has an inflammatory effect. In some embodiments, the solution ofsolid water particles is administered topically and orally. In thismanner, the solution of solid water particles is operable to inhibitbacteria and virus growth in the mouth, gums, teeth, ears, nose, skin,eyes, penis, and vulva. For example, FIGS. 7A and 7B illustrate an X-rayimage of teeth from an individual suffering from gum and tooth decay,where FIG. 7A shows the teeth before treatment with an inorganicsolution of solid water particles. FIG. 7B shows the teeth aftertreatment.

Further, the solution of solid water particles reduces pain andinflammation of the teeth and oral cavity, caused by gingilis andperiodontitis. The solution of solid water particles reduces pain andinflammation in the gums and teeth, whereby the solution of solid waterparticles is held in the mouth for a duration. The inorganic solution ofSWP may be administered topically or orally. In one experimentalembodiment, drinking and dropping the inorganic solution of SWP into theeyes has an inflammatory effect.

The method 100 also comprise a Step 106 of inducing, through theelectric field generated by the solid water particles, polarization ofthe bacterium. It is known in the art that when an SWP cluster 202 isfirst created, it is small, but has very strong electric field. SmallerSWP clusters combine to form bigger ones, which have comparativelysmaller net strong electric field, because most of the electric fieldfrom the smaller ones are neutralized. The larger the SWP clusters, thesmaller the electric field. The smallest SWP clusters that have thestrongest electric field lie on the outer region of the rod are the onesthat cause the explosion of the bacterium 204, and the death.

In another possible embodiment, a Step comprises manipulating a magnetor a magnetic metamaterial between proximal and distal positions fromthe solution of solid water particles to further induce the generatedelectric field. This can include swaying the magnet in front of theaffected part of the body in which the solid water particles areadministered. The dipole effect is increased, as the magneticmetamaterial or a magnet is moved away from the solid water particles.Those skilled in the art will recognize that dipole moment is a resultof multiplication of the magnitude of charges (Q) and the distancebetween them. Thus, when a proton and electron get closer (bond lengthdecreases), polarity decreases hence the dipole decreases. When theymove further away from each other (bond length increases), the polarityincreases and hence dipole moment increases. In one non-limitingembodiment, the magnetic metamaterial may include a silver nanostrip anda thick silver film.

FIG. 6 illustrates a graphical representation of the bacterium 500 shownin FIG. 5 bursting after engaging a rod shaped SWP cluster 400. As shownin the FIG. 6, when the polarized bacterium 500 touches the rod shapedSWP cluster 400 and cannot move any further, the electrostaticattractive force builds up sufficient internal pressure to burst openthe cell wall 600 of the bacterium 500.

The rod shaped SWP cluster 400 has an electric positive dipole 502 thatemits a strong electric field. The bacterium 500 has an electric dipole504. The electric field generated by the positive dipole 502 works topolarize the bacteria in the proximal area of the SWP cluster 400, andattract the bacterium 500. As the bacterium 500 is attracted atincreasing speed towards the SWP cluster 400, the bacterium 500eventually engages the SWP cluster 400.

The surface of the SWP cluster is generally solid and rigid relative tothe bacterium 500. On the surface of the SWP cluster 400, the smallestrod is 30 to 50 nanometer in size. The SWP cluster 400 is generallysolid, and bacterium 500 bursts upon engaging this rigid surface, asshown in FIGS. 2 and 3.

A further Step 110 of the method 100 comprises, whereby the polarizationgenerates an internal pressure in the bacterium. The SWP clusters areoperable to generate a strong electric field that emits from its alignedelectric dipole moment of its water molecules. This strong electricfield will polarize any bacteria which happens to be near. The dipolesof water molecules inside the bacteria will be realigned along thestrong electric field from SWP. The bacteria will become stronglypolarized with a very large electric dipole moment.

This is shown in FIG. 5, which shows a graphic representation of theinduced polarization of the bacterium 500 by the rod shaped SWP cluster400 shown in FIG. 4. The thin oval structure on the left is the rodshaped SWP cluster 400. The positive dipole 502 shows the partialpositive charge is on the right. The bacterium 500 is attracted to thedipole of the rod shaped SWP cluster 400 because of the inducedpolarization of the water inside the cell.

Thus, the electric potential energy U between two electric dipoles is:

U=−p _(s) ·p _(b)/(4 πεr ³)

Where p_(s) is the electric dipole moment of the SWP cluster 400, p_(b)the induced electric dipole moment of the bacteria, ε the dielectricconstant of vacuum, and r is the distance between the SWP cluster 400and the bacterium 500. As the bacterium 500 gets closer to SWP cluster400, it sees a stronger electric field from the SWP cluster 400. Insidethe effective small volume of SWP that finally touches the bacterium500, the electric dipoles of all water molecules is assumed to be linedup. So the total effective electric dipole moment of SWP cluster 400becomes

P _(s) =N _(s) p ₀,

where N_(s) is the effective number of water molecules that line upinside the effective volume of SWP cluster 400. To a first orderapproximation the bacterium 500 could be regarded as consisting of watermolecules, so the induced electric dipole moment of the bacterium 500becomes:

P _(b) =N _(b) p ₀

where N_(b) is the effective number of water molecules inside thebacterium 500. After the bacteria and the SWP cluster 400 engage, theshortest effective distance becomes d. Let the electric dipole moment begiven by

P ₀ =ed ₀,

where do is the size of the water molecule. The internal pressure P_(b)inside the bacterium 500 near the SWC cluster 400 is equal to theelectric energy per unit volume:

P _(b) −U/V,

The effective volume of the bacterium 500 is shown in FIG. 6 asapproximately

V=(d/2)³

The number of effective water molecules with electric dipoles lined upin SWP clusters 400 and bacterium 500 become:

N _(s)=(d/d ₀)³/8

N _(b)=(d/d ₀)³/8

Then the pressure inside the bacterium 500 becomes:

$\begin{matrix}{P_{b} = {U/d^{3}}} \\{= {U_{0}/\left( {64\mspace{11mu} d_{0}^{3}} \right)}}\end{matrix}$

where U₀ is the electric energy of one water molecule due to its owndipole:

U ₀ =e ²/(4πε₀ d ₀)

Putting in the numerical value for the size of water molecule d₀ to be0.3 nm, we get U₀ to be 2.4 eV. The internal pressure inside thebacterium 500 becomes approximately

-   -   P_(b)=2,220 atmospheric pressure, which is huge, and can easily        burst the cell wall of the bacteria and causes it to die.

A final Step 112 of the method 100 comprises, whereby the cell walls ofthe bacterium are destroyed by the internal pressure. Generally, thecell walls 502 of the bacterium 500 burst under the internal pressure.The bursting of bacterium 500 is caused by a physical mechanism. Thedeath of the bacterium 500 is immediate.

The administration of the solution of solid water particles is key tothe efficacy. Thus, the method 100 is administered orally and to theeyes to inhibit growth of bacteria. Experimentally, the method 100provides evidence of antibacterial action in humans. In addition, theantibacterial action is evident in tooth decay that occurs in the humanmouth. For example, FIGS. 7A and 7B illustrate X-ray images 700, 702 ofteeth from an individual suffering from gum and tooth decay. The image700 of FIG. 7A shows the teeth before treatment with SWP. The image 702of FIG. 7B shows the teeth after treatment. As can be seen, image 700displays tooth decay evident by a darkened portion 704 that has beencircled. The bottom image shows a lack of this decay evidencing repair.

In FIG. 7A, the X-ray image of the teeth show the decay state of the gumand teeth. After applying the SWP for several days, gum and tooth repairoccurs as shown in the FIG. 7B X-ray image 702. In yet another example,evidence of antibacterial action is visible through thermographs. Anexperiment was conducted by taking a set of thermal images of the leftand right side of the head; asking the individual to drink an 2 ounce ofthe inorganic solution of SWP; waiting 15 minutes; taking another set ofthermal images of the left and right side of the head; and comparingbefore and after pictures.

If the SWP produced no effect, there would be no change in temperature.If the SWP had an effect, there were changes in temperature. As acontrol, FIG. 8 illustrates a woman who has no tooth problem, and henceno inflammation shown on the cheek. There is no change in temperaturedistribution of the cheek before after drinking the inorganic solutionof SWP.

Looking again at FIG. 8, the thermograph images of two control subjects800 and 802 of with no dental problems is shown. The two left hand sideimages are images of these two individuals before drinking solutionswith solid water particles. The two right hand side images are images ofthese two individuals after drinking solutions with solid waterparticles. The color code of the thermograph is as follows: the hottestportions of the body are shown in white spots 804, with the colorgradient going from red to blue to black from hot to cold.

As illustrated, there are no white spots or even red area in the moutharea, and there is no change of temperature before and after drinkingsolution with solid water particles. This indicates that there is nodental problem for these two individuals 800 and 802. For comparison weshow hottest area 804, shown in white area in neck area (upper images),and ear area (lower images), cool down from drinking solution with solidwater particles, change in size and color from drinking solution withsolid water particles.

Turning to FIG. 9, an exemplary thermal image showing the before andafter thermograph images 900, 902 of a woman suffering from toothproblems. The top thermographs are the before and after (left and rightrespectively) of the woman with dental problems. As can be seen in thethermograph images, there are two white spots 904 on the left indicatinginflammation, chiefly from bacteria. After drinking the inorganicsolution of SWP, the temperature and inflammation of the individual wentdown in image 902.

The bottom images 906, 908 are of a man suffering from tooth problems.Similar to the top pictures, the man's tooth problems are evidenced byone white spot and one red spot 910 on the before image 906. Afterdrinking the solution of SWP, or holding the solution for a period oftime in the mouth, the temperature also decreased, as evidenced in theafter image 908.

Thus, FIG. 9 illustrates graphically the teeth problems on the left sideof the mouth cavity of the woman 900, 902, and the man 906, 908. Theserious bacterial issues are shown in either white dot 904 or red dot910. After drinking the solution of SWP, the white and red dots 904, 910vanish, indicating the inflammation caused by the bacteria has subsided,which can be used as evidence that the bacteria in the teeth decay havebeen killed.

FIG. 10 illustrates thermograph images 1000, 1002 of an individualsimilar to FIG. 9, The left image 1000 is a thermograph of an individualwith a dental problem. The hot spots can be seen as white spots 1004 andred spots 1006, indicating bacterial inflammation. About 15 minutesafter treatment the right thermograph reveals that temperature andinflammation is reduced. In FIG. 10, the teeth and gum problems of themouth cavity on the right side are shown as a white spot 1004 and redspot 1006. After drinking the inorganic solution of SWP, the temperaturedecreases to become a red spot 1008 and pale-yellow area 1010. This isevidence that inflammation caused by the bacteria has subsided, or thatthe majority of the bacteria has been killed.

In some embodiments, the method 100 provides numerous means foradministering the SWP inorganic solution. For example, the SWP inorganicsolution can be used to substitute antibiotics where they are usedcurrently. As SWP has the ability to kill bacteria, it may be applicablein food preservation. The food can be any solid food such as animalfeed. The food can be any liquid such as oil of any kind, such as oliveoil, flexi oil, any cooking oil.

Superbugs are bacteria that develop drug-resistant ability. Most currentantibiotics disrupt the biochemical reactions of the bacteria.Specifically, they inhibit DNA synthesis, RNA synthesis, cell wallsynthesis, or protein synthesis of the bacteria. Superbugs do notdevelop electric-field resistant ability. As SWP kills bacteria withextremely high electric field., so it will kill and inhibit the growthof superbugs, which are resistant to current antibiotics.

As discussed above, the method 100 is effective for killing organisms,beyond bacteria. In one embodiment, the method 100 is applicable onanimals and plants to kill bacteria. In another embodiment, the method100 works substantially the same for killing viruses that are enclosedwithin a membrane, i.e., an enveloped virus. The SWP attracts theseviruses to its surface. Upon touching the SWP, the membrane, or theenvelope of the virus immediately bursts and dies.

As shown below, the classes of Enveloped Viruses that contain HumanPathogens may include, without limitation:

A: DNA viruses, Herpes viruses, Poxviruses, Hepadnaviruses

B: RNA viruses, such as HIV, Flavivirus, Toga virus, Coronavirus,Hepatitis D, Orthomyxovirus, Paramyxovirus, Rhabdovirus, Bunya virus,Filo virus, valiola

C: Retroviruses and Hepadnavirus.

In conclusion, the method 100 for administering solid water particles toprevent bacteria growth in living organisms utilizes a solid waterparticle (SWP) solution to attract and kill a bacterium throughpolarization. The method inhibits growth of a bacterium or an envelopedvirus with an inorganic solution comprised substantially of SWP. The SWPkill the bacterium by providing a solution comprised substantially ofSWP having inherent dipole characteristics that generate an electricfield.

Further, the electric field generated by the SWP attracts the bacterium.Once engaged, the bacterium cannot move. The electric field also createssufficient internal pressure in the bacterium, which bursts the cellwalls of the bacterium, thereby killing bacterium. This mechanism alsokills superbug, which are drug resistant bacteria. The method is alsoefficacious for killing enveloped viruses in the same manner. Further,administering the SWP solution into the mouth for a duration, helpsreduce tooth pain and treat periodontal diseases

These and other advantages of the invention will be further understoodand appreciated by those skilled in the art by reference to thefollowing written specification, claims and appended drawings.

Because many modifications, variations, and changes in detail can bemade to the described preferred embodiments of the invention, it isintended that all matters in the foregoing description and shown in theaccompanying drawings be interpreted as illustrative and not in alimiting sense. Thus, the scope of the invention should be determined bythe appended claims and their legal equivalence.

What is claimed is:
 1. A method for administering solid water particlesto prevent bacteria growth in living organisms, the method comprising:providing a solution of solid water particles, the solid water particlesdefined by an electrical dipole operable to generate an electric field;administering the solution of solid water particles on an affected areahaving a bacterium; inducing, through the electric field generated bythe solid water particles, polarization of the bacterium; whereby thebacterium is electrically drawn to the solid water particles; wherebythe polarization generates an internal pressure in the bacterium; andwhereby the cell walls of the bacterium are destroyed by the internalpressure.
 2. The method of claim 1, wherein the solution of solid waterparticles is operable to prevent the growth of a superbug.
 3. The methodof claim 1, wherein the solution of solid water particles is operable toprevent growth of an enveloped virus.
 4. The method of claim 1, whereinthe method is configured to inhibit bacteria growth in livestock.
 5. Themethod of claim 4, wherein the livestock includes at least one memberselected from the group consisting of: chickens, cows, sheep, andhorses.
 6. The method of claim 1, wherein the solid water particlecomprises a plurality of solid water particles that form a cluster. 7.The method of claim 1, wherein the cluster of solid water particles isrod shaped.
 8. The method of claim 1, wherein the solid water particleis the solvent in the solution.
 9. The method of claim 1, wherein thesolution of solid water particles is administered topically and orally.10. The method of claim 1, wherein the solution of solid water particlesis operable to inhibit bacteria and virus growth in the mouth, gums,teeth, ears, nose, skin, eyes, penis, and vulva.
 11. The method of claim10, wherein the solution of solid water particles reduces pain andinflammation of the teeth and oral cavity, caused by gingilis andperiodontitis.
 12. The method of claim 10, wherein the solution of solidwater particles reduces pain and inflammation in the gums and teeth,whereby the solution of solid water particles is held in the mouth for aduration.
 13. A method for administering solid water particles toprevent bacteria growth in living organisms, the method comprising:providing a solution of solid water particles; administering thesolution of solid water particles orally to an affected area having abacterium;
 14. The method of claim 13, wherein the solution of solidwater particles is operable to prevent the growth of a superbug and anenveloped virus.
 15. The method of claim 13, wherein the solid waterparticles defined by a positive dipole operable to generate an electricfield, the solid water particles comprising a plurality of solid waterparticles that form a rod-shaped cluster.
 16. The method of claim 15,wherein the method comprises: inducing, through the electric fieldgenerated by the solid water particles, polarization of the bacterium;whereby the bacterium is electrically drawn to the solid waterparticles; whereby the polarization generates an internal pressure inthe bacterium; and whereby the cell walls of the bacterium are destroyedby the internal pressure.